EP3317544A1 - Vortex pump - Google Patents

Abstract

Vortex pump with an impeller (2). Said impeller (2) comprises blades (7) for delivering solids-containing media. The blades (7) are arranged in bundles (12). The distance (14) of the blades (7) in said bundles (12) is smaller than the distance (13) of the bundles (12) from each other.

Description

 description

Vortex pump

The invention relates to a free-flow pump with an impeller having blades for conveying solids-containing media.

Such free-flow pumps are also referred to as vortical pumps whose capacity is transmitted from a rotating disk provided with blades, the so-called free-flow, to the flow medium. Free-flow impellers are particularly suitable for conveying media mixed with solid admixtures, such as dirty water. The free-flow impeller is a radial impeller which has a large passage for the solids contained in the pumped medium and is less susceptible to interference.

WO 2004/065796 A1 describes a free-flow pump for conveying liquids mixed with solid admixtures. There is a gap between the impeller and the suction-side housing wall so that solids can pass through the free-flow pump without blockages. The transition of the suction-side housing wall to the wall of the housing space located radially to the impeller is infinitely variable. The case room is asymmetrically designed.

In EP 1 616 100 B1, a free-flow pump is described whose impeller consists of a support disk equipped with open blades. The blades have different heights. A suction-side housing wall is conical. The distance of the housing wall to the leading edges of the higher blades of the impeller decreases with the diameter. A passage having a minimum extension follows a leading edge of a blade of lesser height inclined towards the impeller. As ball passage a free, unused impeller passage is called. It describes the largest permissible diameter of the solids to ensure a clog-free passage. It is given as ball diameter in millimeters. The ball passage corresponds at most to the nominal diameter of the suction or discharge nozzle. So that this maximum possible ball passage is achieved with conventional free-flow pumps, the distance of the blade front to the suction-side housing wall must also correspond at least to the nominal width of the suction or pressure port within the housing. If the paddle-free space between the blade front and the opposite housing wall exceeds a certain level, the efficiency of the free-flow pump is reduced. The larger the distance between the impeller and the suction side

Housing wall is, the lower the efficiency of the free-flow pump. The object of the invention is to provide a free-flow pump, which can promote media with larger solids and thereby has a design according to highest possible efficiency. The free-flow pump should be characterized by the most cost-effective method of production and ensure a long service life. In addition, the free-stream pump should be as versatile as possible and less susceptible to interference, and have a favorable NPSH value. Cavitation damage should be avoided.

This object is achieved by a free-flow pump with the features of claim 1. Preferred variants can be found in the subclaims, the description and the drawings.

According to the invention, the blades are arranged in bundles on the free-flow impeller. The distance between the blades within the bundles is smaller than the distance between the bundles. Due to the construction according to the invention a sufficient ball passage is ensured at a high pumping efficiency of the pump. The bundle arrangement of the blades on the support plate makes it possible to reduce the distance between the inlet-side housing wall and the blade front while still ensuring a sufficient ball passage. Since the distances between the bundles are greater than the spacings of the blades in the bundles, even in the event that the distance of the blade front of the impeller is smaller than the inner diameter of the suction or the discharge nozzle ensures a sufficiently large ball passage. As a result, blockages are avoided while achieving a high efficiency in the promotion. The bundled arrangement of the blades allows the distance of the impeller to the suction side

To reduce the housing wall, without causing blockages. This increases the efficiency of the free-flow pump.

Preferably, the distance of the blade front of the impeller is less than 90%, in particular less than 80%, of the diameter of the suction mouth or of the inner diameter of the suction nozzle.

Each bundle comprises at least two blades. Bundles with two or three blades prove to be particularly favorable. In a variant of the invention, each bundle comprises four blades.

The support disk of the free-flow impeller has a hub projection formed on the suction side, against which the blades engage. The blades protrude from the support disk in the suction-side direction and have a curved against the direction of rotation course. All blades can have the same curvature. In an alternative variant, the blades have different curvatures. For example, blades with different curvature can be arranged within a bundle. Conveniently, the spacing of the blades in the bundles is less than 90%, preferably less than 80%, in particular less than 70%, of the distance of the bundles from each other. In a particularly advantageous embodiment of the invention, the free-stream impeller comprises two bundles of blades, which are preferably arranged offset by 180 ° to each other. It proves to be beneficial if each bundle comprises the same number of blades.

The distances of the blades within the bundles and / or the distances of the bundles from each other are preferably indicated as the angle of the blade pitch. According to the invention, the angles of the blade pitch within the bundles are smaller than the angles of the blade pitch between the bundles.

Expediently, the angles of the blade pitch between the bundles are more than 60 °, preferably more than 70 °, in particular more than 80 °. It proves favorable if the angles of the blade spacing within the bundles are less than 70 °, preferably less than 60 °, in particular less than 50 °.

In a particularly advantageous embodiment of the invention, the impeller is integrally formed with the blades. It proves to be advantageous if the impeller and / or the blades are made of a metallic material. Preferably, a casting material is used.

In a variant of the invention, the angles of the blade pitch between the bundles are not an integer multiple of the angle of the blade pitch within the bundles, so that the bundle arrangement is not due to an impeller with blades of equal angular pitch at which individual blades are omitted.

In a particularly favorable variant of the invention, the height of the blades decreases in the radial direction in relation to a reference plane. The decrease preferably takes place with a bevel angle of more than 2 °, in particular more than 3 °. It proves to be favorable if the decrease in the height of the blades takes place with a bevel angle of less than 8 °, in particular less than 7 °.

Further Merkmaie and advantages of the invention will become apparent from the description of embodiments with reference to drawings and from the drawings themselves.

Showing:

FIG. 1 shows a schematic meridian section through a free-flow pump,

FIG. 2 is a perspective view of a free-flow impeller with two bundles, each having two blades,

FIG. 3 is a plan view of the free-flow impeller as shown in FIG. 2;

FIG. 4 shows a perspective view of a freewheel wheel with two bundles, each of which has three blades,

FIG. 5 is a plan view of the free-flow impeller as shown in FIG. 4;

FIG. 6 shows an arrangement of a free-flow impeller in a pump housing,

7 shows a plan view of a free-stream impeller with a section line A-A, FIG. 8 shows a sectional view along the line A-A of the one shown in FIG

 Vortex wheel.

FIG. 1 shows a free-flow pump in whose housing 1 an impeller 2 is positioned. The impeller 2 is rotatably connected to a shaft, which is not shown in Figure 1. The attachment of the impeller 2 is a hub body 4, which has a bore 5 for screwing a screw. The impeller 2 is designed as a freewheel. On a support disk 6 of the impeller 2 a plurality of blades 7 are arranged. Between the impeller 2 and the inlet-side housing wall 8, a blade-free space 9 is formed.

The suction mouth 10 is formed by a suction-side housing part 11. Of the

Suction orifice 10 forms an inlet for the solids-containing medium and has a diameter D. The suction-side housing part 11 is designed as a suction cover.

The impeller 2 is arranged in a pump housing 15. The front side of the free-flow impeller 2 has at its outer edge a distance A to the inside of the suction-side housing part 11. In this case, the distance A is preferably defined as the distance that a normal, which is perpendicular to the suction side

Housing wall 8 is, the outer edge of the blade front of the impeller 2 has. The distance A is smaller than the diameter D.

The height h of the blades 7 decreases in the radial direction, so that the blade front has a slightly oblique or conical shape

Figure 2 shows a perspective view of the impeller 2, which is designed as a freewheel. The impeller 2 is an open radial wheel which has no cover disk.

On the support disk 6, two bundles 12 are arranged on blades 7. Each bundle 12 comprises two blades 7 each. The two bundles 12 are arranged offset by 180 ° relative to one another on the hub body 4 of the rotor 2.

Figure 3 shows a plan view of the impeller 2 as shown in Figure 2. The distance 13 between the bundles has an angle of the blade pitch of 20 °. The distance 14 of the blades 7 within the bundles 12 has an angle of 60 ° Schaufelteiiung. Thus, the angle blade pitch between the bundles 12 is larger by a factor of 2 than the angles of the blade pitch within the bundles. The Wave your hand! The blade pitch between the bundles 12 is an integer multiple of the blade pitch angle within the bundles 2.

FIG. 4 shows a perspective view of an impeller 2 in which two bundles 12 are arranged on blades 7 on a carrier disk 6, each bundle 12 comprising three blades 7 in each case. The two bundles are arranged offset by 180 ° to each other on the hub body 4 of the impeller 2.

Figure 5 shows a plan view of the impeller 2 as shown in Figure 4. The distance 13 between the bundles 12 has an angle of Schaufelteiiung of 84 °. The distance 14 of the blades 7 within the bundles 12 has an angle of 48 ° Schaufelteiiung. Thus, the angles of the vanes between the bundles are by a factor of 1.75 greater than the angles of the vane pitch within the bundles 12. The angles of blade pitch between the frets! 12 are thus not an integer multiple of the angles of the blade pitch within the bundles 12.

Figure 6 shows a Bück in the free-flow pump, in which an impeller 2 in the

Pump housing 15 is arranged. The housing is a spiral housing. The solids-containing medium leaves the free-flow pump through a pressure connection 17.

Figure 7 shows the impeller 2 as shown in Figure 6 with a section line A-A. FIG. 8 shows a section along this line A-A. The height h of the blades 7 decreases in the radial direction, that is to the impeller outer diameter, from. The decrease is in relation to a reference plane 16, which is partially shown in dashed lines in FIG. In Ausführungsbeispie! the decrease takes place with a bevel angle a of 5 °.

Figure 8 shows a ball 18 in an upper and a lower position. The ball 18 has a diameter d and a radius a. According to the lower position of the Kuge! 18 immerses the ball 18 by a depth b in the spaces of the impeller 2 between the bundles 12 a. This submerged segment of the sphere has a secant c. By arranging the blades 7 in bundles 12 according to the invention, it is possible for a ball having a diameter d corresponding to the diameter of the suction mouth D to immerse a depth b in the spaces between the bundles 12. As a result, the distance A of the blade front to the suction-side housing wall 1 can be reduced by this depth b from the diameter d, so that the free-flow pump has a higher efficiency and yet ensures the maximum ball passage d of the diameter D of the suction port 10. Between the distance A, the depth b and the diameter D is the following relationship:

A + b = D (formula 1).

The depth b can be calculated as follows:

(Formula 2).

Claims

Claims: Free-flow pump 1. Free-flow pump with an impeller (2), the Schaufein (7) for conveying solids-containing media, characterized in that Blades (7) are arranged in bundles (12), wherein the distance (14) of the blades (7) within the bundles (12) is smaller than the distance (3) of the bundles (12) to each other. 2. Free-flow pump according to claim 1, characterized in that each bundle (12) has at least two blades (7). 3. Free-flow pump according to claim 1 or 2, characterized in that each bundle (12) comprises at most four blades (7). 4. Free-flow pump according to one of claims 1 to 3, characterized in that the distance (14) of the blades (7) in the bundles (12) less than 90%, in particular less than 80%, of the distance of the bundles (12) to each other is. 5. free-flow pump according to one of claims 1 to 4, characterized in that the angles of the blade pitch between the bundles (12) more than 60 °, preferably more than 70 °, in particular more than 80 °, amount. 6. free-flow pump according to one of claims 1 to 5, characterized in that the angles of the blade pitch within the bundles (12) less than 70 °, preferably less than 60 °, in particular less than 50 °, amount. 7. free-flow pump according to one of claims 1 to 6, characterized in that the impeller (2) with the blades (7) is integrally formed. 8. free-flow pump according to one of claims 1 to 7, characterized in that the impeller (2) and / or the blades (7) made of a metallic material, preferably a cast material, are made. 9. free-flow pump according to one of claims 1 to 8, characterized in that the distance (A) of the blade front at the outer radius of the impeller (2) to the suction-side housing wall (11) less than 90%, in particular less than 80%, of the diameter ( D) of the inlet opening and / or the outlet opening is. 10. free-stream impeller according to one of claims 1 to 9, characterized in that each bundle (12) comprises an equal number of blades (7). 11. Free-flow pump according to one of claims 1 to 10, characterized in that the bundles (12) are arranged offset by 180 ° to each other. 12. Free-flow pump according to one of claims 1 to 11, characterized in that the angle of the blade pitch between the bundles (12) by more than the Factor 1, 2, preferably more than the factor 1, 4, in particular more than the factor 1, 6, are greater than the angles of the blade pitch within the bundles (12). 13. The free-flow pump according to one of claims 1 to 12, characterized in that the angles of the blade pitch between the bundles (12) are not an integer multiple of the angle of the blade pitch within the bundles (12). 14. Free-flow pump according to one of claims 1 to 13, characterized in that the height (h) of the blades (7) decreases in the radial direction, wherein the decrease preferably with a chamfer angle (a) of more than 2 °, in particular more than 3 ° and / or less than 8 °, in particular less than 7 °. 15. Free-flow pump according to one of claims 1 to 14, characterized in that between the bundles (12) spaces for immersion of a ball about a depth (b) are arranged. 16. Free-flow pump according to one of claims 1 to 15, characterized in that all blades (7) have the same curvature. 17, free-flow pump according to one of claims 1 to 15, characterized in that the blades (7) within the bundles (12) have different curvatures.